Histological Description and Histometric Assessment of the Peripheral Blood Cells in the Saw-Scaled Viper (Echis carinatus sochureki)

World Journal of Zoology 8 (1): 47-51, 2013 ISSN 1817-3098 IDOSI Publications, 2013 DOI: 10.5829/idosi.wjz.2013.8.1.71213 Histological Description and Histometric Assessment of the Peripheral Blood Cells in the Saw-Scaled Viper (Echis carinatus sochureki) Ali Louei Monfared Department of Basic Sciences, Division of anatomy and histology, Faculty of Para-Veterinary Medicine, University of Ilam, Ilam, Iran Abstract: A histological and histometrical study of peripheral blood cells of saw-scaled viper (Echis carinatus sochureki) from southwestern Iran was performed. Blood smears were prepared immediately, air-dried and differential leukocytes count were done. Also, histometric measurements of the various blood cells were carried out. The characteristic shape of the saw-scaled viper erythrocytes was oval and enucleated. Overall, five types of the leucocytes include heterophils, eosinophils, basophils, lymphocytes and monocytes were observed in the peripheral blood smears. The results of the present study are useful for the scientists involved in snake conservation around the world and emphasize the usefulness of the microscopic studies in viper conservation. Key words: Histology Histometry Blood cells Echis carinatus sochureki INTRODUCTION description and histometric assessment of the peripheral blood cells in the saw-scaled viper (Echis carinatus The snake fauna of Ilam province, southwestern Iran sochureki). has the most biodiversity due to variety of climatic MATERIALS AND METHODS regimes of this province and also diverse of geographic condition such as mountains, alluvial fans and sandy area Study area was Ilam province which is located in the and gypsum hills [1]. In addition, it has been reported that western and southwestern regions of the Iranian Plateau of 87 species and subspecies of snakes recorded in Iran between 31 58' and 34 15' N and 45 24' and 48 10' E. Echis [2], approximately 31% occur in Ilam province [2, 3]. carinatus sochureki had been rehabilitated in the wildlife Since reptiles are very sensitive to changes of habitat laboratory of the Para-veterinary medicine college in the checking their blood parameters may guide the evaluation Ilam University (Ilam, Iran). The snakes were identified of physiological and health conditions and may be used according to Latifi [11] descriptions using morphometric as a good indicator in determining environmental measurements, coloration and pholidosis features [11]. conditions [4-7]. In addition, due to need for conservation Blood samples were collected from ventral caudal vein actions [8], diagnostic evaluation of reptiles [9], economic just before the vipers were set free, when they were importance of species and comparative study [10]; a clinically normal and in good physical condition. thorough knowledge of reptilian blood histology is Twenty blood smears for each snake were prepared becoming more imperative. immediately and air-dried. For differential leukocytes Echis carinatus sochureki is a venomous viper count the blood smears of each viper were stained with a species found in parts of the world including western Iran. quick Romanowsky-type stain, Diff Quick (QD), according At the first time, taxonomy, morphology, distribution and to the manufacturer's instructions. Two hundred habitat of the saw-scaled viper from Ilam province were leukocytes were counted for each blood smear for described by Latifi [11] but there is not a comprehensive differential relative count. In addition, for description of study on the blood cell morphologies of this specie. So, the microscopic characteristics of the blood cells the the present work was performed to obtain the histological blood smears were soon stained with Wright's and Giemsa Corresponding Author: Ali Louei Monfared, Pajoohesh Street, Bangonjab, University of Ilam, Ilam, Iran. Tel: +98-8412222015, +989183419098, Fax: +98-8412222015. 47

method. The stained smears were studied under a light anisocytosis. Their shape was oval and enucleated. microscope (Nikon Eclipse E800) and appropriate The erythrocytes have a violet-blue ellipsoidal sometimes photographs of the blood cells were taken with a digital indented nuclei uniformly localized in a central part of the camera (Nikon, China) and stored. cell. On smears stained with Wright's and Giemsa method, For histometric assessment, from each blood smear, the cytoplasm were light pale pink and the chromaphilic 100 erythrocytes were randomly chosen for the nuclei were dark purplish blue. (Fig. 1-1). measurement of their lengths (L), widths (W), nuclear In the present work, leukocytes of saw-scaled snakes lengths (NL) and nuclear widths (NW). Erythrocyte sizes were categorized into 5 groups; heterophils, eosinophils, (ES) and their nuclei sizes (NS) were computed from basophils, lymphocytes and monocytes. Measurements ES= LW /4 and NS= NLNW /4. Comparisons of cell and on the various leukocytes and also thrombocytes in the nuclear shapes were done from L/W and NL/NW ratios blood smear of the saw-scaled viper are given in Table 3. and that of nucleus/cytoplasm from NS/ES ratio. From the Heterophils were the largest of the leukocytes and blood smears of each snake, measurements of leucocytes average 11.59 µm in diameter. They were the most (lymphocytes, monocytes, neutrophils, eosinophils, prevalent circulating cells and contained large numbers of basophils) and thrombocytes (TL, TW) were also taken to irregular shape, dull eosinophilic granules. Their nuclei determine their sizes. One way ANOVA test was utilized were round and usually placed close to the cells periphery in the comparisons of the obtained data, = 0.05 in all of and in the most cases, hetrophils granules were not seen the analyses. easily. When the nucleus was centrally located, it acquired a round form (Fig. 1-2). RESULTS Eosinophils contained numerous round and light blue granules that often occluded visualization of The results of the leukocyte differential count from the nucleus. They relatively were large-sized cells saw-scaled viper are inserted in the Table 1. Heterophils (10.83 µm in diameter) with a generally eccentric, round, were the most numerous cells among various leukocyte darkly stained nuclei. (Fig. 1-3). Basophils were very low, cells, followed by lymphocytes. Basophils, monocytes average 5.1 µm in diameter and were slightly smaller than and eosinophils were very small number in the white Basophils were difficult to find in the peripheral blood cells count. blood smears of the saw-scaled viper. These cells were The erythrocyte lengths, widths, sizes, L/W ratios, round and contained a violet-blue with generally eccentric nuclear measurements of the erythrocytes and also nucleus. Their purplish black cytoplasmic granules nucleocytoplasmic rations (NS/ES) are given in Table 2. masked the nuclei, so their shapes were not readily Erythrocytes were homogeneous in color but moderately distinguishable (Fig. 1-4). Table 1: Mean± standard deviation and range of the leukocyte differential count values of saw-scaled viper White blood cells Mean ± standard deviation Range Heterophils (%) 74.89 ± 6.37 49.66-85.38 Eosinophils(%) 1.02 ± 0.03 0. 4-1.94 Basophiles (%) 1.96 ± 0.09 0.1-3.98 Lymphocytes (%) 15.45 ± 3.92 12.87-27.14 Monocytes (%) 5.97 ± 0.38 3.69-8.24 Table 2: Mean± standard deviation of the erythrocyte measurements and dimensions of their nuclei on blood smears of the saw-scaled viper Erythrocyte measurements Erythrocyte nuclei dimensions -------------------------------------------------------------------------------- ---------------------------------------------------------------------------------------------------------------- L(µm) W(µm) L/W 2 ES(µm ) NL(µm) NW(µm) NL/NW 2 NS(µm ) NS/ES 8.05 ± 0.05 5.92 ± 0.46 1.42 ± 0.03 96.9 ± 3.27 4.56 ± 0.02 3.85 ± 0.04 1.19 ± 0.17 28.82 ± 0.68 0.29 ± 0.02 Table 3: Mean± standard deviation of the various leukocytes and thrombocytes measurements on blood smears of the saw-scaled viper Leukocytes Thrombocytes ----------------------------------------------------------------------------------------------------------------------------------------------------- ------------------------------------ Hetrophil (µm) Eosinophil(µm) Basophil (µm) Small lymphocyte (µm) Large lymphocyte (µm) Monocyte (µm) TL (µm) TW (µm) 11.59 ± 0.12 10.83 ± 0.02 5.18 ± 0.04 6.29 ± 0.93 7.75 ± 0.48 11.42 ± 0.15 4.85 ± 0.08 4.67 ± 0.01 48

Fig. 1: Photomicrograph of the morphological observations on the peripheral blood cells from saw-scaled viper (Echis carinatus sochureki).1): erythrocyte, 2): hetrophil, 3): eosinophil, 4):basophils, 5):large lymphocyte, 6):small lymphocyte, 7): monocyte and 8): thrombocyte. Wright-Giemsa, 1000. In the blood smears, both small and large Heterophils were the most numerous leukocytes in lymphocytes were observed. Large lymphocytes had a the leukocyte count of saw-scaled viper, followed by relatively wider zone of cytoplasm and well- defined round lymphocytes which are similar to that reported for Turkish purplish blue nucleus (Fig. 1-5).In small lymphocytes, the vipers [12] and other reptiles include sea turtles [14]. nuclei were prominently clumped chromatin and Previous studies have demonstrated the mature surrounded by a rim of moderator basophilic cytoplasm. erythrocytes of reptiles are permanently nucleated and On the other word, cytoplasm was pushed to a side as a blunt-ended ellipsoids [15]. Similarly, the erythrocytes small peripheral zone (Fig. 1-6). identified in our study were oval and enucleated, just like Monocytes were large cells and had a round or those of other reptilian vertebrates and those of birds. amoeboid shape. Their nucleus was purple-blue, just Also, the morphologic characteristics of erythrocytes kidney-like form or fusiform, typically eccentric location from saw-scaled viper in this study were similar to those and had a chromatin pattern slightly less clumped than described in Turkish Viperidae snakes [12]. However, that of the large lymphocytes. The cytoplasm was weak to there was not literature data on the saw-scaled viper slightly basophilic and sometimes containing variably erythrocyte morphology with which comparison could be sized intracytoplasmic vacuoles (Fig.1-7). made. Thrombocytes were round cells which were observed Regarding blood cell morphologies, it has been as groups of three or more cells in the peripheral blood suggested that reptiles constitute a heterogeneous group smears. The nuclei was generally round, quite among vertebrate [16]. We classified five types of white chromaphilic and filling the whole cell. Under the Wright s blood cells in the peripheral blood smears of the sawstain, these cells were similar to the small lymphocytes in scaled viper: heterophils, eosinophils, basophils, size but could be differentiated by their very pale lymphocytes ands monocytes. These results agree with coloration cytoplasm (Fig. 1-8). the observations on some Turkish snakes [12] and of Sypek and Borysenko on various reptiles [17]. DISCUSSION Histological description and histometric assessment of the heterophils from saw-scaled viper in the present In this work, the leukocyte differential count from work were similar to those reported for Turkish snakes saw-scaled viper was similar to those of Turkish snakes [12] and other reptiles [14, 16,17]. In addition, in line with [12] but different from the observations of Salakij et al. these results it has been demonstrated that heterophils in [13] on the water snakes (Homalopsis buccata). This the reptiles are generally round cells with eosinophilic dissimilarity in results may be originates from the fusiform cytoplasmic granules and clear cytoplasm [14]. existence of multi-parasitic infestations include Reptilian heterophils have a similar function to that Hepatozoon sp. Trypanosome and Haemogregarina sp. performed by neutrophils in mammals [18] and neutrophils in that study. are rare in reptiles, although these cells have been 49

demonstrated in the tuatara (Sphenodon punctatus) [19]. REFERENCES In the present study, we did not identify neutrophils in the saw-scaled viper. These results agree with the 1. Fathinia, B., N. Rastegar-Pouyani, H. Darvishnia and observations of Arikan et al. [12] on some Turkish M. Rajabizadeh, 2010. The snake fauna of Ilam viperids snakes. Morphological descriptions of the Province, southwestern Iran. Iranian Journal of eosinophils and basophils from saw-scaled viper were Animal Biosystematics, 6(1): 9-23. similar to those reported on the Turkish vipers [12] except 2. Rastegar-pouyani, N., H.G. Kami, M. Rajabizadeh, for their size which were smaller than Turkish snakes. S. Shafaei and S.C. Aanderson, 2008. Annotated Lymphocytes from saw-scaled viper were checklist of Amphibians and Reptiles of Iran. histologically and histometrically similar to those reported Iranian Journal of Animal Biosystematics for various Turkish snakes [12]. These cells were not 4: 43-66. difficult to distinguish from other peripheral blood cells by 3. Bostanchi, H., S.C. Anderson, H.G. Kami and their well- defined round purplish blue nucleus as well as T.J. Papenfuss, 2006. A new species of rim of moderator basophilic cytoplasm. However, it has Pseudocerastes with elaborate tail ornamentation been suggested that lymphocytes from other species of from western Iran (Squamata: Viperidae). Proceedings reptiles can be difficult to distinguish from thrombocytes of the California Academy of Sciences. Fourth Series, [20]. 57(14): 443-450. Based on the results obtained during present study, 4. Jacobson, E.R., J.M. Gaskin, M.B. Brown, H.K. Harris, monocytes were relatively large cells and had a nucleus C.H. Gardiner, J.L. LaPointe, H.P. Adams and with eccentric location as well as a slightly basophilic C. Reggiardo, 1991. Chronic upper respiratory cytoplasm which sometimes containing variably sized tract disease of free-ranging desert tortoises intra-cytoplasmic vacuoles. Similarly, Arikan et al. [12] (Xerobates agasizii). Journal of Wildlife Diseases, reported the same morphological features of the peripheral 27: 296-316. blood monocytes on the Turkish snakes [12]. 5. Raphael, B.L., M.W. Klemens, P. Moehlman, E. Previous researchers has been identified azurophils Dierenfeld and W.B. Karesh, 1994. Blood values in as a separate cell type in the peripheral blood smears of free-ranging pancake tortoises (Malacochersus reptiles, but in the present study we did not identify tornieri). Journal of Zoo and Wildlife Medicine, azurophils in the saw-scaled viper. Similarly, no azurophils 25: 63-67. were reported in the peripheral blood cells described from 6. Dickinson, V.M., J.L. Jarchow and M.H. Trueblood, various Turkish snakes [12]. 2002. Hematology and plasma biochemistry reference Some authors described the thrombocytes in various range values for free-ranging desert tortoises in reptiles as elliptical to fusiform nucleated cells, with Arizona. Journal of Wildlife Diseases, 38: 143-153. centrally positioned extremely chromophilic nuclei and 7. Lopez-Olivera, J.R., J. Montane, I. Marco, typically clear cytoplasm which may contain a few A. Martinez-Silvestre, J. Soler and S. Lavin, 2003. azurophilic granules [14-16, 20]. Also, it has been reported Effect of venipuncture site on hematologic and serum that activated thrombocytes appear as clusters of cells biochemical parameters in marginated tortoise with irregular cytoplasmic margins and vacuoles and (Testudo marginiata). Journal of Wildlife Diseases, appear devoid of cytoplasm when aggregated [15]. 39: 830-836. The present study established the presence of 8. Martínez Silvestre, A., M.A. Rodríguez Dominguez, thrombocytes with round-shaped cells which were similar J.A. Mateo, J. Pastor, I. Marco, S. Lavín and to the lymphocytes but could be differentiated by their R. Cuenca, 2004. Comparative haematology and very pale coloration cytoplasm. blood chemistry of endangered lizards Owing to the absence of previous studies on blood (Gallotia species) in the Canary Islands. Vet. Rec., cells in the saw-scaled viper, the current study provides 155: 266-269. baseline data regarding morphologic classification of 9. Campbell, T.W., 2004. Hematology of reptiles. In: blood cells in these vipers. Further study will be needed Thrall, M.A. (org.), Veterinary Hematology and to describe the ultra structural properties of the peripheral Clinical Chemistry. Lippincott Williams & Wilkins, blood cells from this specie. Philadelphia, USA. pp: 259-276. 50

10. Bonadiman, S.F., G.C. Stratievsky, J.A. Machado, 17. Sypek, J. and M. Borysenko, Reptiles. 1988. In: A.P. Albernaz, G.R. Rabelo and R.A. DaMatta, 2009. Rowley AF, Ratcliffe NA, eds. Vertebrate Blood Cells. Leukocyte ultrastructure, hematological and serum Cambridge, UK: Cambridge University Press; pp: 211- biochemical profles of ostriches (Struthio camelus). 256. Poult. Sci., 88: 2298-2306. 18. Mertens, R.F.W., 1957. Weitere unterlagen zur 11. Latifi, M., 2000. The Snakes of Iran. 3rd Persian herpetofauna von Iran 1956. Jahreshefte desvereins Edition, Tehran [in Farsi]. fur vaterlandische Naturkunde in Wurtemberg, 12. Arikan, H., B. Gocmen, M.K. Atatur, Y. Kumlutas and 112: 118-128. K. Cicek, 2009. Morphology of peripheral blood cells 19. Montali, R.J., 1988. Comparative pathology of from various Turkish snakes. North-Western Journal inflammation in the higher vertebrates (reptiles, birds of Zoology. 5(1): 61-73. and mammals). Journal of Comparative Pathology, 13. Salakij, C., J. Salakij, P. Suthunmapinunta and 99: 1-26. L. Chanhome, 2002. Hematology, morphology and 20. Desser, S.S., 1978. Morphological, cytochemical and ultrastructure of blood cells and blood parasites from biochemical observations on the blood of the tuatara, Puff-faced water snakes (Homalopsis buccata). Sphenodon punctatus New Zealand Journal of Kasetsart J. Nat. Sci., 36: 35-43. Zoology, 5: 503-508. 14. Casal, A.B. and J. Oros, 2007. Morphologic and 21. Alleman, A.R., E.R. Jacobson and R.E. Raskin, 1999. cytochemical characteristics of blood cells of juvenile Morphologic, cytochemical staining and loggerhead sea turtles (Caretta caretta). Research in u9ltrstructural characteristics of blood cells from Veterinary Science, 82: 158-165. eastern diamondback rattlesnakes (Crotalus 15. Campbell, T.W., 2006. Clinical pathology of reptiles. adamanteus). American Journal of Veterinary In: Mader DR, ed. Reptile Medicine and Surgery. Research, 60: 507-514. Second edition. St. Louis, MO: Saunders Elsevier; pp: 453-470. 16. Saint Girons, M.C., 1970. Morphology of the circulating blood cells. pp: 73-91. In: Gans C. and Parsons T. S. (eds.) Biology of Reptilia (Vol. 3), Academic Press. 51